DE1906571B2 - Rod or wire concrete prestressing element anchorage - with compressed wedge only elastically deformed and embracing element as monolithic clamp - Google Patents

Abstract

The anchoring device is for wire, rod or cable type reinforcing elements, especially prestressing members and comprises a wedge socket and one or more wedge units to clamp the element in this of softer material. This material is firm enough in the compressed condition for the wedge to be only elastically deformed by the forces occurring. The wedge piece encloses the reinforcing element in the manner of one piece clamp. There are grooves on part of the exterior surface of the wedge piece, arranged and shaped to effect the intended distribution of clamping forces. The slit in the wedge piece preferably meets the edge sockets spherical surface vertically. The advantages of soft and hard wedges are combined.

Description

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45 The invention relates to an anchoring device for rod, wire or rope-shaped reinforcement elements, in particular for prestressing members, which has a wedge sleeve and at least one wedge piece which clamps the reinforcement element into this and which is made of a softer material than the reinforcement element.

In the known anchoring devices of the scr type, the reinforcement element is ode by two More wedge pieces clamped inside the wedge sleeve The wedge pieces are made of very soft, plastic deformable material such. B. aluminum. When the wedges are pressed in, the reinforcement element is pressed ment into the wedges. so that they partially encompass the reinforcement element and thus a special one effective connection between the reinforcement element and the wedge pieces is achieved.

It has been shown that if such an anchorage is subjected to constant stress, the reinforcement element is pulled out over time as a result of the flowing deformation of the wedge material. It is here dk same phenomenon can be observed as cable stays that are made by casting, for example from a zinc alloy.

This undesirable phenomenon can be avoided if a material is used for the wedges that is harder than the material of the reinforcement element to be anchored. However, here occur other undesirable ones Effects on. Once there is the risk that when clamping the reinforcement element its surface injured and thus, .., olge one Notch effect the fatigue strength of the reinforcement element is significantly impaired. Come in addition another serious drawback. The wedge pieces must be made very precisely because they keep their shape can no longer change when pressing in.

Here, the fact must be taken into account that with an annular wedge sleeve, the cone-shaped wedges consisting of / white or several sectors only fit in a very specific axial position. the individual wedge sectors are initially in the middle of their outer circumference and then when they are pressed in with their outer edges on the inner surface of the wedge sleeve. They are designed to be in the assumed end position exactly into the conical bore of the wedge sleeve. However, since the end position depends on the Depending on the external dimensions of the anchorage element to be anchored, there is not always a match be guaranteed with the predetermined position and thus not a uniform force from the sleeve over the wedges onto the reinforcement element.

By the magazine "Beton- und Stahlbetonbau", issue 3, 1954, p. 61 is a round wedge for tendons became known, which has four longitudinal slots, one of which goes all the way through, but not the rest completely, so that the four individual wedges at the lower ends are held together for the sake of simplification tier assembly. The round wedge works with Press in roughly like four individual wedges and assign, if the wedge material, as usual, harder than that anchoring reinforcement element, the disadvantages described above.

The object of the invention is it. a Ver; tnkc '"ungsvorrichiung to create the d: c advantageous properties of an anchorage by means of a soft potting compound or by means of very soft wedges - high bonding effect and uniform application of force - and anchoring using hard wedges - avoid the

Pulling out under long-term stress - unified in itself without being afflicted with their disadvantages.

The invention is characterized in that the wedge material in the pressed-in state is so large Strength is such that the forces occurring in the wedge are only able to ν. -Form the wedge elastically and that the wedge encloses the reinforcing element in the manner of a one-piece clamp and at least a part of the outer surface of the wedge piece grooves are provided, their arrangement and shape such are chosen that the intended distribution, in particular one over the scope of the to be anchored Reinforcement element evenly distributed, which causes clamping forces.

Due to the clamp-like design of the wedge piece, an almost complete enclosure of the Reinforcement element reached. The grooves give the wedge or wedges a targeted local one Lent deformability or resilience, which allows the clamping forces emanating from the wedge sleeve evenly or in the intended distribution on the reinforcement element to be anchored To have an effect.

The invention is of particular importance in the anchoring of rope-shaped concrete reinforcement elements. zs As a result of the uniform application of force, all the individual wires of the reinforcement element are anchored equally well.

The local deformability when pressing in the wedges, which ensures uniform force penetration, can be influenced not only by the arrangement of the grooves but also by the shape of the grooves will. The intended value of the local deformability can be determined by the depth, width and spacing of the grooves to be changed.

Are on the adjoining! 'Laugh two neighbors Provide wedge body grooves, these are preferably attached perpendicular to each other.

It is particularly advantageous if - as already proposed - the reinforcement element adjacent inner surface of the wedge grooves aulweisi. This makes it possible to use the shear bond or to enlarge the contact area between the reinforcement element and the wedge piece. One on the Reinforcement element applied profile (.1 moves then into the grooved inner surface of the wedge gap. The best effect is achieved when the grooves are roughly perpendicular to an existing surface profiling a rod-shaped reinforcement element or run roughly perpendicular to the stroke of a sciliform reinforcement element.

The wedge material should be softer in its initial state than the material to be anchored Reinforcement clemenies so as not to damage it when the wedges are pressed in, but it must not be used under any circumstances have as great a deformability as the usual ones Potting compounds in which the disadvantageous phenomenon mentioned occurs. The ratio of Strength values or hardness / between the anchoring reinforcement element and the wedge mate f> o rial depends on the formation of the surface of the reinforcement element. Serves as a reinforcement element For example, reinforcing steel provided with inclined ribs or otherwise surface profiled, see above determines the lower limit of the hard ties ''? Wedge material by the Seherbeanspruchimg pressed in between the ribs in the pressed-in state Wedge material. This must be able to absorb the shear forces that occur. At a Reinforcement element with a smooth surface is the permissible lower limit of the hardness of the wedge material significantly higher. To prevent the reinforcement element from being subjected to stress over time is pulled out, is a hardship of the Keilmaierial required, which corresponds almost to the hardness of the reinforcement element.

1st - as pointed out above as particularly advantageous - the one adjacent to the reinforcement element The inner surface of the wedge piece is provided with grooves, so occurs when the wedge piece or pieces are pressed in as a result of the Cold deformation of the wedge material causes local solidification. which increases the hardness at this point so much. ■ In the final state, judge them to be the same or even a little larger than the hardness of the reinforcement element to be anchored can be tes. The latter is especially important for the Anchoring of wire-like or rope-like reinforcement elements with a smooth surface.

Steel is generally used as the material for the wedge material. It is suitable for example

a) for a tensioning rope made of St 180 as wedge material St 140. if the inner surface adjoining the tensioning rope of the wedge is provided with grooves.

b) for a reinforcing bar made of St 160 with a rectangular or oval cross-section, its surface is provided with ribs of small height. as wedge material St 60 to St 70, if the inner surface of the wedge is grooved.

c) for a reinforcement bar made of St IbO with a round cross-section and ribs greater than Wedge material St 50. if the inner surface of the wedge piece is grooved. and St 40. if the inner surface of the wedge is not grooved.

This choice of wedge material ensures that that after the pressing in of the wedge pieces, the forces occurring in them only close the wedge material elastically like to deform.

Embodiments of the invention are explained using eight figures.

It each show in longitudinal section and in plan view

F i g. 1 and 2 an anchoring device with a single wedge for receiving a rod or rope-shaped reinforcement elements.

F i g. 3 and 4 an anchoring device with six pieces of Kcil, which are arranged in the form of sectors of an annular wedge tint ¹ each receive a reinforcement element,

I- "i g. 5 and 6 one corresponding to the 1 i g. J and 4 corresponding Anchoring device in which the wedge pieces are in the form of sectors of two ring wedges fitted into one another are trained, and

7 and 8 show an anchoring device for reinforcing bars which are oval in cross section.

The in the F i g. 1 and 2 shown anchoring device contains a wedge sleeve I. Wedge piece 2. which encloses a seven-wire tension cable 3 like a one-piece clamp. In Fig. 1 this is For the sake of simplifying the illustration, tensioning cable is not shown. The clamp-like wedge 2 has a longitudinal slit. 4 and on the outer surface of the opposite side longitudinal grooves 5. The depth of the The longitudinal grooves take place in the circumferential direction from the point 6 opposite the shaft to both sides down. The inner surface of the wedge gap is ribbed i provided, which run approximately in the circumferential direction. Dk outer edges 8 of the longitudinal slot of the keii pieces: are rounded. The anchoring device is in

State shown before the wedge was pressed in.

Due to the clamp-like shape of the wedge piece is in connection with the longitudinal grooves 5 when pressing the Wedge piece 2 causes a uniform encircling of the tension cable 3. The individual wires of the Tension ropes are gripped evenly. So that the outer slot edges of the wedge cannot impair the closing process, they are rounded. As a result of the ribs 7 of the inner surface of the wedge piece, there is also a local deformability here or resilience, due to which the wedge material partially into the depressions on the Surface of the tension cable can penetrate. The inner contour of the wedge fits the outer contour of the tension cable and thereby improves the shear bond. Very cheap are the conditions when the ribs 7 are approximately perpendicular to the twist or lay of the tensioning cable 3 get lost.

The grooves 5 can be different not only in the circumferential direction but also in the longitudinal direction Have depth. This measure will be provided if you move in the axial direction of the tension cable wants a different clamping force. For example, takes the depth of the longitudinal grooves 5 in the in F i g. 1 from top to bottom, a zone is created in the lower area of the wedge greater deformability created. When the wedge is pressed in, there is less force in this zone than in the upper area, in which the deformability is lower. This allows you to have a Uniform power transmission from the wedge sleeve to the tensioning cable over the length of the clamping pin reach.

The grooves can be used to achieve the intended local deformability or resilience of the Wedge gap 2 material different shape, different depth, different distance and have different arrangement.

In the F i g. 3 and 4 is an anchoring device shown, which contains six wedge pieces 9 within a wedge sleeve 38. The wedge pieces are in the shape of Sectors of a ring wedge arranged. They each enclose a rope-shaped one like a one-piece clamp Concrete reinforcement element and have grooves It and 12 on part of their outer surfaces. The grooves 12 extend approximately perpendicular to the axis of the ring wedge, the grooves 11 approximately parallel to it. The inner surface of each Keilstüekes is provided with circumferential ribs t3. In addition, the slot surfaces are to each other vertically arranged grooves 14 and 15 are provided. Since the grooves 11 and 12 in the radial direction of the ring wedge extend only about as far to the outside as it corresponds to the depth of the slots 16 when the Ring wedge due to the mutual abutment of the smooth outer surfaces 17 and 18 of the wedge pieces The slots 16 are pressed together, thereby enclosing the tensioning cable 10. Inside, with the Riilcn 11 and 12 provided area 19 of the ring wedge Due to the local deformability of the adjoining surfaces, initially only a limited power transmission possible. So there are significantly lower peripheral forces here. The ribs 11 and 12 are of this type arranged and designed that in the course of the press-fitting of the ring wedge one over the circumference of the Tension ropes 10 uniform training of the clamping forces is achieved. The inner area of the ring wedge is compressed so far in the end position that it becomes Stüt / .gewölbe acts for the individual tension ropes 10, the is necessary for an even distribution of the clamping force along the circumference of each tension cable. In the Circumferential ribs 13 are pressed in when the ring wedge is pressed together, the individual wires of the rope. This creates a good shear bond.

In general, the width of the slots 16 of the wedge pieces is chosen so that the slot in the final State is not completely closed in order to prevent the reinforcement element to be anchored from getting around forms a supporting arch that can no longer exert clamping forces on the reinforcement element. A However, complete closing of the slot is then possible without this risk, even if the slot surfaces are also included Grooves, which are preferably transverse to one another, are provided. In the present case - as already mentioned - such grooves 14 and 15 are provided.

Figures 5 and 6 show an anchoring device, the sector-like wedge pieces 20 and 21 of two

ίο contains interlocking ring wedges. So on the Slots 22 of the outer wedge pieces and the slots 23 of the inner wedge pieces exerted approximately the same closing force, must next to the previous one Embodiment explained conditions still add the condition that the slope of the conical Contact area 24 to the ratio between the total number of inner wedges and the total number the outer wedge pieces is adapted. Has - as in the present case - the inner ring wedge six and the outer ring wedge twelve segment-like wedge pieces, then the conical surface 24 must be about half the slope as the have outer conical surface 25 resting on the wedge sleeve.

In this embodiment, too, the fact that the individual wedge pieces at certain points yielding, so that they are in these places have a deformability, when the ring wedges are pressed in at the same time, an even distribution the clamping forces achieved along the circumference of the reinforcement elements to be anchored. The anchorage can be understood as a steel package compressed by a wedge sleeve into which the to induce core reinforcement elements are inserted, and in which by grooves - i.e. by a constructive means - Deformability is achieved at very specific points or cutting planes of the package, through which the mutually supporting forces are reduced within the package, so that in terms of Clamping effect on the reinforcement elements to be anchored a similar behavior is achieved as with a soft potting compound. In contrast to this, however, the package has elastic properties of a high-strength steel, which has the effect that occurs with cast rope anchors, namely the Pulling out the reinforcement elements prevented.

The in the F i g. 7 and 8 shown embodiment shows an anchoring of surface profiled cn Reinforcing bars 26 with an oval cross-section. Eight wedge pieces 28 are located within a wedge sleeve 27 arranged to form the sectors of a ring wedge. The wedge pieces 28 each enclose in the manner of a one-piece clamp the respective rebar and are - similar to the previous embodiments - on part of the outer surface with

<·. *> Giving away longitudinal grooves 29 and transverse grooves 30. In addition, the inner surfaces of the Keilstückc with transverse to Surface profiling of the reinforcing bar arranged ribs 31 give away. These ribs are the

Only indicated at one point for the sake of clarity.

Due to the radial arrangement of oval lobes. several advantages are achieved in the manner illustrated. The bundle of rods is given a rigidity that is particularly desirable for ground anchors. Also work The splitting tensile forces are not as one-sided as, for example, when the bars are arranged at right angles. As a result of the grooves 29 and 30 then occurs when - as in the present case - the wedge material between two adjacent rebar is not too thick. a particularly desirable effect. it will be that Keiimatcrial even with slight forces due to its elastic properties in the space between two ribs pressed in and thus increases the shear bond.

5 Although as embodiments of the invention nui End anchors have been described 'own', fell the invention of course also for a butt joint of concrete reinforcement elements. In this case are two end anchors of the described type

ίο arranged in opposite directions and the wedge sleeves kraftsehiüs sig connected to each other.

For this purpose 4 sheets of drawings

Claims (10)

Patent claims: 1. Anchoring device for rod, wire or rope-shaped reinforcement elements, in particular for Prestressing members which have a wedge sleeve and at least one reinforcing element which clamps in this Has wedge, which consists of softer material than the reinforcing element, thereby featured that the wedge material! in the pressed-in state is so strong that the wedge (2, 9, 20, 21, 28) occurring forces to deform the wedge only elastically, and that the wedge piece the Reinforcing element (3, 10, 26) encloses in the manner of a one-piece clamp and at least a part of the outer surfaces of the wedge piece grooves (5, II, 12,29,30) are provided, their arrangement and shape are chosen such that the intended distribution of the clamping forces is effected. 2. Anchoring device according to claim J. characterized in that the arrangement and shape of the grooves are chosen such that a uniform distribution of the clamping forces is effected over the circumference of the reinforcing element to be anchored. 3. Anchoring device according to claim 1 or 2, characterized in that the slot (4, 16, 22, 23) of the wedge piece meets the conical surface of the wedge sleeve approximately perpendicularly. 4. Anchoring device according to one of claims 1 to 3, characterized in that the Wedge pieces (9, 20, 21, 28) form sectors of at least one ring wedge and that the contact surfaces adjacent wedge pieces are at least partially provided with adjacent grooves (11, 12, 29, 30) are. 5. Anchoring device according to claim 4, characterized in that the abutting Grooves (11,12,29,30) at the ßerühriingsstellen each two adjacent Kcil pieces (9, 28) approximately perpendicular to each other, preferably longitudinally or transversely are arranged to the edges of the contact surfaces. 6. Anchoring device according to one of claims I to 5, characterized in that the Slotted surfaces of the wedge piece or the wedge pieces are preferably arranged perpendicular to one another adjoining Have grooves (14,15). 7. Anchoring device according to one of claims 1 to 6, characterized in that the 5 " outer edges (8) of the slot (4) are rounded. 8. Anchoring device according to one of claims 1 to 7, characterized in that the has ribs (7, 13) adjoining the reinforcement element inside surface of the wedge piece, which ss preferably run perpendicular to any surface profiling of the reinforcement element. 9. Anchoring device according to one of claims I to 8, characterized in that the <> o grooves along their course of varying depth. Width and / or different distance from each other to have. 10. Anchoring device according to claim 1, characterized marked / eichnei. that the grooves are designed and arranged in such a way that the radial clamping forces are greater towards the end of the reinforcement element. 25th